Chiang Mai J. Sci. 2008; 35(1) KC-019 171 Chiang Mai J. Sci. 2008; 35(1) : 171-177 www.science.cmu.ac.th/journal-science/josci.html Contributed Paper Acetaldehyde Production from Ethanol over Ni-Based Catalysts Arthit Neramittagapong*[a, b], Wiphada Attaphaiboon [a], Sutasinee Neramittagapong [c] [a] Department of Chemical Engineering, Faculty of Engineering, Khon Kaen University, Khon Kaen 40002, Thailand. [b] Research Center for Environmental and Hazardous Substance Management (EHSM), Khon Kaen University, Khon Kaen 40002, Thailand. [c] Department of Chemical Engineering, Faculty of Engineering, King Mongkut s Institute of Technology Ladkrabang, Bangkok 10520, Thailand. *Author for correspondence; e-mail: artner@kku.ac.th Received : 28 September 2007 Accepted : 16 November 2007 ABSTRACT The aim of this work was to study the catalytic ethanol dehydrogenation to acetaldehyde over nickel based catalysts. SnO 2, Al 2 and SiO 2 were used as supporting materials. The reactions were carried out in a catalytic flow system operated in the temperature range of 200 and 350 o C under atmospheric pressure. Various parameters such as Ni loading, a kind of supporting materials, contact time on the ethanol conversion and selectivity to acetaldehyde were investigated. The main product in all cases is acetaldehyde, with secondary products such as ethyl acetate and diethyl ether. It has been found that showed the highest ethanol conversion with high selectivity to acetaldehyde. The 10 wt% exhibited the highest yield of acetaldehyde at 300 o C with low contact time (0.05g min ml -1 ). The deactivation of 10 wt% was occurred after 200 minutes on stream due to the formation of Ni Sn alloy phase. Keywords: Acetaldehyde, Dehydrogenation, Ethanol. 1. INTRODUCTION Acetaldehyde is an organic chemical compound, which is used as an intermediate for the synthesis of other chemicals. It can be used as a raw material for the production of acetic acid, acetic anhydride, ethyl acetate, butyl aldehyde, crotonaldehyde, pyridine, peracetic acid and vinyl acetate. Acetaldehyde is also used as a solvent in the production of rubber, in tanning of leather, in the paper industry, as a fruit and fish preservative, as a flavoring agent, as a denaturant for alcohol and in composition of fuel. Acetaldehyde can be synthesized by various methods including partial oxidation of ethanol or ethylene (reaction (1) and (2)), hydration of acetylene (reaction (3)) and ethanol dehydrogenation (reaction (4)). The disadvantages of partial oxidation method are
172 Chiang Mai J. Sci. 2008; 35(1) using an expensive catalyst and high reaction temperature [1-2]. The hydration of acetylene involves the use of mercury as mercuric complex which is a toxic material [2]. Thus, the alternative ethanol dehydrogenation method has been very interesting for producing acetaldehyde. This method uses only one reactant, ethanol, which can be synthesized from more abundant resources such as fermentation of agricultural products. Additionally, the co-product of this reaction is hydrogen, which can be used as energy source for fuel cell. Partial oxidation of ethanol or ethylene CH 2 OH + O 2 CHO+H 2 O (1) C 2 H 4 + O 2 CHO (2) Hydration of acetylene C 2 H 2 + H 2 O CHO (3) Ethanol dehydrogenation CH 2 OH CHO + H 2 (4) Chang et al. [3] reported that dehydrogenation of ethanol using copper catalyst exhibited very high activity for dehydrogenation of ethanol into acetaldehyde. However, the application of copper catalyst is usually confined to rapid deactivation, which results predominantly from sintering due to the inherently low melting point of copper metal phase. Badlani and Wachs [4] studied methanol conversion over various types of metal oxides and found that NiO could promote the dehydrogenation of methanol into formaldehyde. Thus, nickel based catalysts were interested for the catalytic ethanol dehydrogenation into acetaldehyde. This research has been focus on the ethanol dehydrogenation over supported Ni catalysts. The effects of various parameters such as Ni loading, a kind of supporting materials and contact time on ethanol conversion and selectivity to acetaldehyde were investigated and reported. 2. MATERIALS AND METHODS 2.1 Catalyst preparation Ni based catalysts were prepared by impregnation method. SnO 2, Al 2 and SiO 2 were used as supporting materials. Ni(N ) 2 was used as a Ni precursor. The Ni loading was set up to 5, 10 or 15 wt% by varying the nickel nitrate concentrations. The supported was impregnated with an aqueous solution of nickel nitrate. The impregnated solid was dried in oven at 110 o C over night. After drying, the dried samples were calcined in air at 400 o C for 2 h. 2.2 Catalyst characterization Identification of the fresh and spent catalyst phases was performed by X-ray diffraction analysis using a Bruker D 8 Advance diffractometer. The patterns were run with nickel-filtered copper radiation (l=1.5405). The X-ray tube was operated at 40 kv and 25 ma. 2.3 Ethanol dehydrogenation reaction Ethanol dehydrogenation was carried out in a conventional fixed-bed flow-type reaction system as shown in Figure 1. Ethanol was fed into the reactor using nitrogen as carrier gas with the concentration of 10% ethanol at standard gas condition (total flow rate of 20 or 40 ml min -1 ). The reactions were carried out in the temperature range of 200 and 350 o C. The reaction temperatures were measured at the center of the catalyst bed. The compositions of feed and products were analyzed by on-line gas chromatograph (Shimadzu GC 14B) equipped with thermal
Chiang Mai J. Sci. 2008; 35(1) 173 conductivity and flame ionization detectors, and Porapak-Q separating column. The ethanol conversion, acetaldehyde selectivity and yield, and contact time were calculated according to the following formulae: (5) (6) (7) (8) Where: EtOH con. = Ethanol conversion AcH selc. = Acetaldehyde selectivity AcH yield = Acetaldehyde yield Figure 1. Equipment of the Ethanol dehydrogenation system. (1) N 2 gas (2) Ethanol tank (3) Pump (4) Vaporizer (5) Reactor (6) Catalyst bed (7) Gas chromatograph 3. RESULTS AND DISCUSSION 3.1 Ethanol dehydrogenation over Ni-based catalysts The ethanol conversion and acetaldehyde selectivity over Ni based catalysts in the temperature range between 200 and 350 o C were summarized in Table 1. The results given in Table 1 indicate that all of supported 5 wt%
174 Chiang Mai J. Sci. 2008; 35(1) Ni catalysts exhibit high selectivity to acetaldehyde more than 75% at the reaction temperatures of 200 o C and 250 o C. Further, in case of all the supported Ni catalysts gave low ethanol conversion excluding. showed the highest ethanol conversion of 41.48% and acetaldehyde selectivity of 83.73% at 300 o C. It can be seen that ethanol conversion over increased with an increasing of temperature, however, it has been shown the sharply deactivation by increasing of temperature reached up to 350 o C due to the deactivation of catalyst. These results suggested that the was more active and stable for the production of acetaldehyde from ethanol at 300 o C. Table 1. Ethanol conversion and acetaldehyde selectivity at 200 350 o C over Ni based catalysts. Conditions: total flow rate 40 ml/min (10% EtOH), catalyst weight: 1g, 5 wt% Ni loading Temp ( o C) Conversion (%) Acetaldehyde selectivity (%) Ni/Al 2 Ni/SiO 2 Ni/Al 2 Ni/SiO 2 200 1.24 0.29 0.43 100 100 100 250 9.23 1.25 1.99 98.87 77.71 97.98 300 41.48 7.55 7.45 83.73 59.47 77.13 350 33.11 24.64 0 84.07 53.78 0 3.2 Effect of Ni loading The effects of the amount of Ni loading on the ethanol conversion and acetaldehyde selectivity over were investigated and shown in Fig. 2. It has been found that the production of acetaldehyde correlated with Ni loading. The ethanol conversion increased monotonically with the Ni loading up to 10 wt% after that the ethanol conversion and acetaldehyde yield were not changed significantly. It has been suggested that 10 wt% was suitable for the production of acetaldehyde from ethanol. Figure 2. Ethanol conversion and acetaldehyde yield over as a function of Ni loading at 300 o C. Acetaldehyde yield, Ethanol conversion
Chiang Mai J. Sci. 2008; 35(1) 175 3.3 Effect of contact time The effect of contact time on the ethanol dehydrogenation performance of 10%Ni/ SnO 2 at 300 o C has been shown in Figure 3. It was observed that the conversion of ethanol increased up to 62% when the W/F value increased up to 0.15 g min ml -1. The products of this reaction consisted of two main categories. The major product was acetaldehyde (higher than 80%) and the minor product was ethyl acetate. The trace of diethyl ether (less than 1%) was also found, however, it was not concerned to be the main category of the hydrogenation products. The selectivity to acetaldehyde decreased with the increase of the W/F ratio due to the formation of ethyl acetate. It should be noted that the selectivity of acetaldehyde was reached up to 100% at low contact time of 0.05 g min ml -1 or lower. The extrapolation to zero space time indicated that the acetaldehyde was a primary product, and ethyl acetate was produced from the dehydrogenation of acetaldehyde [5]. Figure 3. Ethanol conversion, acetaldehyde and ethyl acetate selectivity over 10 wt% Ni/ SnO 2 as a function of contact time at 300 o C. Conditions: total flow rate 20 ml/ min (10% EtOH); Catalyst weight: 1 g. Acetaldehyde selectivity, Ethanol conversion, Ethyl acetate selectivity 3.4 Catalyst stability The ethanol dehydrogenation over 10 wt% at 300 o C was studied for long period of time in order to confirm the catalyst stability which was very important for the commercial application. During the initial period of the reaction (200 min on stream), the conversion and selectivity of catalyst seem to be constant, however, it can be seen that the deactivation of catalysts was started when the catalyst was used over 200 minutes on stream (Fig. 4). Further, it must be pointed out that there was little or no change in acetaldehyde selectivity with reaction time.
176 Chiang Mai J. Sci. 2008; 35(1) Figure 4. Conversion and selectivity as a function of time 10 wt% at 300 o C. Acetaldehyde selectivity, Ethanol conversion, Conditions: total flow rate 20 ml/min (10% EtOH); catalyst weight: 1 g. Considering the XRD patterns of fresh 10 wt% catalyst shown in Fig. 5 a) showed peaks corresponding to NiO (2θ: 37.28 and 43.25) and SnO 2 (2θ: 26.59, 33.88, 37.956, 38.98, 51.78 and 54.76) but the XRD patterns of catalyst after the reaction showed peaks of Ni Sn (2θ : 30.59, 43.25, 44.60 and 57.56) and SnO 2 as shown in Fig. 5 b). The formation of Ni Sn alloy phase may cause the catalyst deactivation. It is interesting that the acetaldehyde selectivity has been almost constant during the reaction (Fig. 4). This strongly suggests that the formation of Ni Sn phase corresponded to the decreasing of number of active sites but it did not promote any reactions. Figure 5. X-ray diffraction patterns of a) fresh 10 wt% and b) 10 wt% after the reaction at 300 o C for 600 min. ( SnO 2, NiO, Ni-Sn)
Chiang Mai J. Sci. 2008; 35(1) 177 4. CONCLUSION catalysts exhibited better catalytic ethanol dehydrogenation and selectivity to acetaldehyde than Ni/Al 2 and Ni/SiO 2. Acetaldehyde is a primary product of the reaction with ethyl acetate produced as a secondary product. Based on the experimental results, we recommended the with 10 wt% of Ni content and reaction temperature at 300 o C for production of acetaldehyde in order to achieve high activity and good selectivity. Nevertheless, the catalyst deactivation was observed after 200 minutes on stream due to the formation of Ni Sn phase. 5. ACKNOWLEDGEMENTS The authors gratefully thanks for the financial supports from the Khon Kaen University s Graduate Research Grant for academic year 2006 (Grant No. 49141103) and the Royal Thai Government Scholarship program 2006 (No. F 31 111 12 01). REFERENCES [1] Faith, W.L., Keyes, D.B. and Clark, R.L. (1957), Industrial Chemicals, 2 nd ed., Wiley, New York. [2] Marshall, N. (1989), Petrochemical processes: Technical and economic characteristics, Gulf publishing, Texas. [3] Chang, F.W., Yang, H.C., Roselin, L.S., Kuo, W.Y. (2006), Ethanol dehydrogenation over copper catalysts on rice husk ash prepared by ion exchange, Applied Catalysis A: General V.304, 30-39. [4] Badlani, M. and Wachs, I.E. (2001), Methanol: a smart chemical probe molecule, Catalysis Letters V.75 No. 3-4, 137-149. [5] Inui, K., Kurabayashi, T. and Sato, S. (2002), Direct synthesis of ethyl acetate from ethanol carried out under pressure, J. Catal., Vol. 212, 207-215.